Solving an equation with constraintsSelect one among multiple solutions that satisfies a certain condition and 3D Plot it with varying simulation valuesHow to plot a function with two parameters determined by another parameter?How to “Control” the Type of Solutions Mathematica Produces Using the Solve FunctionEquation Solving with NSolveNeed help setting up a numerical simulation and getting output into a tableGet random solution for equation with $n$ parameters and infinite solutions?Solving equation with NSolveGood practice when working with multiple solutions of a system of equationsSolving equation with constraintsUsing constraints when solving a trigometric equationSelect one among multiple solutions that satisfies a certain condition and 3D Plot it with varying simulation values

Finitely generated matrix groups whose eigenvalues are all algebraic

How can a day be of 24 hours?

files created then deleted at every second in tmp directory

Mathematica command that allows it to read my intentions

How to coordinate airplane tickets?

Did 'Cinema Songs' exist during Hiranyakshipu's time?

Why are UK visa biometrics appointments suspended at USCIS Application Support Centers?

Unlock My Phone! February 2018

Send out email when Apex Queueable fails and test it

What Exploit Are These User Agents Trying to Use?

How can saying a song's name be a copyright violation?

Bullying boss launched a smear campaign and made me unemployable

Theorists sure want true answers to this!

How to Prove P(a) → ∀x(P(x) ∨ ¬(x = a)) using Natural Deduction

My ex-girlfriend uses my Apple ID to log in to her iPad. Do I have to give her my Apple ID password to reset it?

Why is it a bad idea to hire a hitman to eliminate most corrupt politicians?

how do we prove that a sum of two periods is still a period?

Can a virus destroy the BIOS of a modern computer?

In Bayesian inference, why are some terms dropped from the posterior predictive?

Where would I need my direct neural interface to be implanted?

What exactly is ineptocracy?

Is it "common practice in Fourier transform spectroscopy to multiply the measured interferogram by an apodizing function"? If so, why?

Ambiguity in the definition of entropy

Placement of More Information/Help Icon button for Radio Buttons

Solving an equation with constraints

Select one among multiple solutions that satisfies a certain condition and 3D Plot it with varying simulation valuesHow to plot a function with two parameters determined by another parameter?How to “Control” the Type of Solutions Mathematica Produces Using the Solve FunctionEquation Solving with NSolveNeed help setting up a numerical simulation and getting output into a tableGet random solution for equation with $n$ parameters and infinite solutions?Solving equation with NSolveGood practice when working with multiple solutions of a system of equationsSolving equation with constraintsUsing constraints when solving a trigometric equationSelect one among multiple solutions that satisfies a certain condition and 3D Plot it with varying simulation values

This is a question that follows up from this post:

Select one among multiple solutions that satisfies a certain condition and 3D Plot it with varying simulation values

I was trying to apply the answer to a more complicated case I am working on, and I'm getting an error message.

To start, here is the code of my more complicated function:

eq = 1/(24 (-1 + r)^3 r^4 s) (3 d^6 (-3 + 5 r) (-1 + t) + 6 d^5 (3 - 5 r + c (-3 + r (9 - 4 q + 8 (-1 + q) r))) (-1 + t) + 12 d (-1 + r)^3 r^2 (s + 2 t) - 4 (-1 + r)^3 r^2 s ((-1 + r^2) s (-1 + t) + 3 t) + 12 d^3 (-1 + r) r (2 + c (-2 + r (5 - 2 q + 4 (-1 + q) r)) + s - r (3 + s + r s) + 2 t - 3 r t + (-1 + r + r^2) s t) + 3 d^4 (3 + c^2 (1 + 2 (-1 + q) r) (-3 + r (7 - 2 q + 6 (-1 + q) r)) (-1 + t) - 2 c (-3 + r (9 - 4 q + 8 (-1 + q) r)) (-1 + t) - 3 t + r (3 + 4 r (-5 + 3 r) + 5 t)) + 12 d^2 (-1 + r) r (-(-1 + c) (s (-1 + t) - 2 t) + r^3 (-1 + c (-1 + q) s (-1 + t) - t) + r^2 (2 + (-1 + c (-1 + 2 q)) s (-1 + t) + (2 + 4 c - 4 c q) t) + r (-1 - (1 + c (-2 + q)) s (-1 + t) + (2 - 5 c + 2 c q) t))) == 0

Among multiple solutions of $r$, I would like to select the positive real $r$ and simulate it with the following simulation values, for example, $d=0.8$, $s=2$, $t=0.02$ and $0<c<1$ and $1<q<2$. I would like to 3DPlot $r$ against $c$ and $q$.

My Mathematica code is as follows:

With[d = 0.8, s = 2, t = 0.02,
 sol = Solve[eq, 0 <= c <= 1, 1 <= q <= 2, r, r > 0]]; 
Plot3D[Evaluate[r /. sol], c, 0, 1, q, 1, 2]

And once run, I get a very long warning message including something like:

Warning: r>0 is not a valid domain specification. Assuming it is a variable to eliminate.

Can anyone help?

edited 3 hours ago

m_goldberg

88.1k872199

asked 5 hours ago

ppp

306111

1

$begingroup$
You should write: Solve[equations, 0 <= c <= 1, 1 <= q <= 2, r > 0, r]. As the error suggests, r > 0 does not belong where you have it in your code.
$endgroup$
– MarcoB
4 hours ago

$begingroup$
d=0.8;s=2;t=0.02;NMinimize[(expr)^2,0<c<1&&1<q<2,r,c,q] rapidly finds a solution near r->0.6457, c->0.1130, q->1.5452 Hopefully that will help you, but it isn't clear to me how you intend to Plot3D that.
$endgroup$
– Bill
4 hours ago

$begingroup$
@Bill: I'm trying to do simulation to see how the solution for r changes for different values of c and q. Would this be possible? In your code, what does (expr)^2 mean?
$endgroup$
– ppp
3 hours ago

$begingroup$
@MarcoB: Would it be possible to simulate (3D Plot) to see how the solution for r changes for different values of c and q? By the way, I'm trying your suggestion, and Mathematica has been running for quite a while. Did you get the answer quickly?
$endgroup$
– ppp
3 hours ago

$begingroup$
(expr)^2 was the square of your really long expression but with the trailing ==0 removed. So you wanted to find where your expression equaled zero and this found where the square of your expression was almost exactly zero. I am not sure there are still solutions for expr==0 if you make tiny changes in c or q or both. There may be some solution in r somewhere else, but not close by. I don't know. I'm guessing that is what you are supposed to learn from your exercise.
$endgroup$
– Bill
2 hours ago

add a comment |

This is a question that follows up from this post:

Select one among multiple solutions that satisfies a certain condition and 3D Plot it with varying simulation values

I was trying to apply the answer to a more complicated case I am working on, and I'm getting an error message.

To start, here is the code of my more complicated function:

eq = 1/(24 (-1 + r)^3 r^4 s) (3 d^6 (-3 + 5 r) (-1 + t) + 6 d^5 (3 - 5 r + c (-3 + r (9 - 4 q + 8 (-1 + q) r))) (-1 + t) + 12 d (-1 + r)^3 r^2 (s + 2 t) - 4 (-1 + r)^3 r^2 s ((-1 + r^2) s (-1 + t) + 3 t) + 12 d^3 (-1 + r) r (2 + c (-2 + r (5 - 2 q + 4 (-1 + q) r)) + s - r (3 + s + r s) + 2 t - 3 r t + (-1 + r + r^2) s t) + 3 d^4 (3 + c^2 (1 + 2 (-1 + q) r) (-3 + r (7 - 2 q + 6 (-1 + q) r)) (-1 + t) - 2 c (-3 + r (9 - 4 q + 8 (-1 + q) r)) (-1 + t) - 3 t + r (3 + 4 r (-5 + 3 r) + 5 t)) + 12 d^2 (-1 + r) r (-(-1 + c) (s (-1 + t) - 2 t) + r^3 (-1 + c (-1 + q) s (-1 + t) - t) + r^2 (2 + (-1 + c (-1 + 2 q)) s (-1 + t) + (2 + 4 c - 4 c q) t) + r (-1 - (1 + c (-2 + q)) s (-1 + t) + (2 - 5 c + 2 c q) t))) == 0

My Mathematica code is as follows:

With[d = 0.8, s = 2, t = 0.02,
 sol = Solve[eq, 0 <= c <= 1, 1 <= q <= 2, r, r > 0]]; 
Plot3D[Evaluate[r /. sol], c, 0, 1, q, 1, 2]

And once run, I get a very long warning message including something like:

Warning: r>0 is not a valid domain specification. Assuming it is a variable to eliminate.

Can anyone help?

edited 3 hours ago

m_goldberg

88.1k872199

asked 5 hours ago

ppp

306111

1

$begingroup$
You should write: Solve[equations, 0 <= c <= 1, 1 <= q <= 2, r > 0, r]. As the error suggests, r > 0 does not belong where you have it in your code.
$endgroup$
– MarcoB
4 hours ago

$begingroup$
d=0.8;s=2;t=0.02;NMinimize[(expr)^2,0<c<1&&1<q<2,r,c,q] rapidly finds a solution near r->0.6457, c->0.1130, q->1.5452 Hopefully that will help you, but it isn't clear to me how you intend to Plot3D that.
$endgroup$
– Bill
4 hours ago

$begingroup$
@Bill: I'm trying to do simulation to see how the solution for r changes for different values of c and q. Would this be possible? In your code, what does (expr)^2 mean?
$endgroup$
– ppp
3 hours ago

$begingroup$
@MarcoB: Would it be possible to simulate (3D Plot) to see how the solution for r changes for different values of c and q? By the way, I'm trying your suggestion, and Mathematica has been running for quite a while. Did you get the answer quickly?
$endgroup$
– ppp
3 hours ago

$begingroup$
(expr)^2 was the square of your really long expression but with the trailing ==0 removed. So you wanted to find where your expression equaled zero and this found where the square of your expression was almost exactly zero. I am not sure there are still solutions for expr==0 if you make tiny changes in c or q or both. There may be some solution in r somewhere else, but not close by. I don't know. I'm guessing that is what you are supposed to learn from your exercise.
$endgroup$
– Bill
2 hours ago

add a comment |

This is a question that follows up from this post:

Select one among multiple solutions that satisfies a certain condition and 3D Plot it with varying simulation values

I was trying to apply the answer to a more complicated case I am working on, and I'm getting an error message.

To start, here is the code of my more complicated function:

eq = 1/(24 (-1 + r)^3 r^4 s) (3 d^6 (-3 + 5 r) (-1 + t) + 6 d^5 (3 - 5 r + c (-3 + r (9 - 4 q + 8 (-1 + q) r))) (-1 + t) + 12 d (-1 + r)^3 r^2 (s + 2 t) - 4 (-1 + r)^3 r^2 s ((-1 + r^2) s (-1 + t) + 3 t) + 12 d^3 (-1 + r) r (2 + c (-2 + r (5 - 2 q + 4 (-1 + q) r)) + s - r (3 + s + r s) + 2 t - 3 r t + (-1 + r + r^2) s t) + 3 d^4 (3 + c^2 (1 + 2 (-1 + q) r) (-3 + r (7 - 2 q + 6 (-1 + q) r)) (-1 + t) - 2 c (-3 + r (9 - 4 q + 8 (-1 + q) r)) (-1 + t) - 3 t + r (3 + 4 r (-5 + 3 r) + 5 t)) + 12 d^2 (-1 + r) r (-(-1 + c) (s (-1 + t) - 2 t) + r^3 (-1 + c (-1 + q) s (-1 + t) - t) + r^2 (2 + (-1 + c (-1 + 2 q)) s (-1 + t) + (2 + 4 c - 4 c q) t) + r (-1 - (1 + c (-2 + q)) s (-1 + t) + (2 - 5 c + 2 c q) t))) == 0

My Mathematica code is as follows:

With[d = 0.8, s = 2, t = 0.02,
 sol = Solve[eq, 0 <= c <= 1, 1 <= q <= 2, r, r > 0]]; 
Plot3D[Evaluate[r /. sol], c, 0, 1, q, 1, 2]

And once run, I get a very long warning message including something like:

Warning: r>0 is not a valid domain specification. Assuming it is a variable to eliminate.

Can anyone help?

edited 3 hours ago

m_goldberg

88.1k872199

asked 5 hours ago

ppp

306111

This is a question that follows up from this post:

Select one among multiple solutions that satisfies a certain condition and 3D Plot it with varying simulation values

I was trying to apply the answer to a more complicated case I am working on, and I'm getting an error message.

To start, here is the code of my more complicated function:

eq = 1/(24 (-1 + r)^3 r^4 s) (3 d^6 (-3 + 5 r) (-1 + t) + 6 d^5 (3 - 5 r + c (-3 + r (9 - 4 q + 8 (-1 + q) r))) (-1 + t) + 12 d (-1 + r)^3 r^2 (s + 2 t) - 4 (-1 + r)^3 r^2 s ((-1 + r^2) s (-1 + t) + 3 t) + 12 d^3 (-1 + r) r (2 + c (-2 + r (5 - 2 q + 4 (-1 + q) r)) + s - r (3 + s + r s) + 2 t - 3 r t + (-1 + r + r^2) s t) + 3 d^4 (3 + c^2 (1 + 2 (-1 + q) r) (-3 + r (7 - 2 q + 6 (-1 + q) r)) (-1 + t) - 2 c (-3 + r (9 - 4 q + 8 (-1 + q) r)) (-1 + t) - 3 t + r (3 + 4 r (-5 + 3 r) + 5 t)) + 12 d^2 (-1 + r) r (-(-1 + c) (s (-1 + t) - 2 t) + r^3 (-1 + c (-1 + q) s (-1 + t) - t) + r^2 (2 + (-1 + c (-1 + 2 q)) s (-1 + t) + (2 + 4 c - 4 c q) t) + r (-1 - (1 + c (-2 + q)) s (-1 + t) + (2 - 5 c + 2 c q) t))) == 0

My Mathematica code is as follows:

With[d = 0.8, s = 2, t = 0.02,
 sol = Solve[eq, 0 <= c <= 1, 1 <= q <= 2, r, r > 0]]; 
Plot3D[Evaluate[r /. sol], c, 0, 1, q, 1, 2]

And once run, I get a very long warning message including something like:

Warning: r>0 is not a valid domain specification. Assuming it is a variable to eliminate.

Can anyone help?

plotting equation-solving

edited 3 hours ago

m_goldberg

88.1k872199

asked 5 hours ago

ppp

306111

edited 3 hours ago

m_goldberg

88.1k872199

asked 5 hours ago

ppp

306111

edited 3 hours ago

m_goldberg

88.1k872199

edited 3 hours ago

m_goldberg

88.1k872199

edited 3 hours ago

m_goldberg

88.1k872199

asked 5 hours ago

ppp

306111

asked 5 hours ago

ppp

306111

asked 5 hours ago

ppp

306111

1

$begingroup$
You should write: Solve[equations, 0 <= c <= 1, 1 <= q <= 2, r > 0, r]. As the error suggests, r > 0 does not belong where you have it in your code.
$endgroup$
– MarcoB
4 hours ago

$begingroup$
d=0.8;s=2;t=0.02;NMinimize[(expr)^2,0<c<1&&1<q<2,r,c,q] rapidly finds a solution near r->0.6457, c->0.1130, q->1.5452 Hopefully that will help you, but it isn't clear to me how you intend to Plot3D that.
$endgroup$
– Bill
4 hours ago

$begingroup$
@Bill: I'm trying to do simulation to see how the solution for r changes for different values of c and q. Would this be possible? In your code, what does (expr)^2 mean?
$endgroup$
– ppp
3 hours ago

$begingroup$
@MarcoB: Would it be possible to simulate (3D Plot) to see how the solution for r changes for different values of c and q? By the way, I'm trying your suggestion, and Mathematica has been running for quite a while. Did you get the answer quickly?
$endgroup$
– ppp
3 hours ago

$begingroup$
(expr)^2 was the square of your really long expression but with the trailing ==0 removed. So you wanted to find where your expression equaled zero and this found where the square of your expression was almost exactly zero. I am not sure there are still solutions for expr==0 if you make tiny changes in c or q or both. There may be some solution in r somewhere else, but not close by. I don't know. I'm guessing that is what you are supposed to learn from your exercise.
$endgroup$
– Bill
2 hours ago

add a comment |

1

$begingroup$
You should write: Solve[equations, 0 <= c <= 1, 1 <= q <= 2, r > 0, r]. As the error suggests, r > 0 does not belong where you have it in your code.
$endgroup$
– MarcoB
4 hours ago

$begingroup$
d=0.8;s=2;t=0.02;NMinimize[(expr)^2,0<c<1&&1<q<2,r,c,q] rapidly finds a solution near r->0.6457, c->0.1130, q->1.5452 Hopefully that will help you, but it isn't clear to me how you intend to Plot3D that.
$endgroup$
– Bill
4 hours ago

$begingroup$
@Bill: I'm trying to do simulation to see how the solution for r changes for different values of c and q. Would this be possible? In your code, what does (expr)^2 mean?
$endgroup$
– ppp
3 hours ago

$begingroup$
@MarcoB: Would it be possible to simulate (3D Plot) to see how the solution for r changes for different values of c and q? By the way, I'm trying your suggestion, and Mathematica has been running for quite a while. Did you get the answer quickly?
$endgroup$
– ppp
3 hours ago

$begingroup$
(expr)^2 was the square of your really long expression but with the trailing ==0 removed. So you wanted to find where your expression equaled zero and this found where the square of your expression was almost exactly zero. I am not sure there are still solutions for expr==0 if you make tiny changes in c or q or both. There may be some solution in r somewhere else, but not close by. I don't know. I'm guessing that is what you are supposed to learn from your exercise.
$endgroup$
– Bill
2 hours ago

You should write: Solve[equations, 0 <= c <= 1, 1 <= q <= 2, r > 0, r]. As the error suggests, r > 0 does not belong where you have it in your code.

– MarcoB
4 hours ago

d=0.8;s=2;t=0.02;NMinimize[(expr)^2,0<c<1&&1<q<2,r,c,q] rapidly finds a solution near r->0.6457, c->0.1130, q->1.5452 Hopefully that will help you, but it isn't clear to me how you intend to Plot3D that.

– Bill
4 hours ago

@Bill: I'm trying to do simulation to see how the solution for r changes for different values of c and q. Would this be possible? In your code, what does (expr)^2 mean?

– ppp
3 hours ago

@MarcoB: Would it be possible to simulate (3D Plot) to see how the solution for r changes for different values of c and q? By the way, I'm trying your suggestion, and Mathematica has been running for quite a while. Did you get the answer quickly?

– ppp
3 hours ago

(expr)^2 was the square of your really long expression but with the trailing ==0 removed. So you wanted to find where your expression equaled zero and this found where the square of your expression was almost exactly zero. I am not sure there are still solutions for expr==0 if you make tiny changes in c or q or both. There may be some solution in r somewhere else, but not close by. I don't know. I'm guessing that is what you are supposed to learn from your exercise.

– Bill
2 hours ago

add a comment |

1 Answer
1

active

oldest

votes

Mathematica's kernel seemed to slow down to a crawl when constraints on c and q were given along with your equation. However, the constraints are enforced in the s plot domain specification, so I thought it would worth trying to solve the equation without them which succeeded. Rationalization of the parameters suppressed all warnings.

Making the plot was a little slow because there seem some regions with very steep gradients that Plot3D has trouble with.

eq = (1/(24 (-1 + r)^3 r^4 s) (3 d^6 (-3 + 5 r) (-1 + t) + 6 d^5 (3 - 5 r + c (-3 + r (9 - 4 q + 8 (-1 + q) r))) (-1 + t) + 12 d (-1 + r)^3 r^2 (s + 2 t) - 4 (-1 + r)^3 r^2 s ((-1 + r^2) s (-1 + t) + 3 t) + 12 d^3 (-1 + r) r (2 + c (-2 + r (5 - 2 q + 4 (-1 + q) r)) + s - r (3 + s + r s) + 2 t - 3 r t + (-1 + r + r^2) s t) + 3 d^4 (3 + c^2 (1 + 2 (-1 + q) r) (-3 + r (7 - 2 q + 6 (-1 + q) r)) (-1 + t) - 2 c (-3 + r (9 - 4 q + 8 (-1 + q) r)) (-1 + t) - 3 t + r (3 + 4 r (-5 + 3 r) + 5 t)) + 12 d^2 (-1 + r) r (-(-1 + c) (s (-1 + t) - 2 t) + r^3 (-1 + c (-1 + q) s (-1 + t) - t) + r^2 (2 + (-1 + c (-1 + 2 q)) s (-1 + t) + (2 + 4 c - 4 c q) t) + r (-1 - (1 + c (-2 + q)) s (-1 + t) + (2 - 5 c + 2 c q) t))));

Module[eqn, soln,
 eqn = With[d = 4/5, s = 2, t = 2/100, Evaluate @ eq];
 soln = Solve[Evaluate @ eqn == 0, r];
 Plot3D[Evaluate[r /. soln], c, 0, 1, q, 1, 2, PlotPoints -> 50]]

plot

Edit

This addresses a issue raised by the OP in a comment below.

Here is way to get numerical values of r.

soln =
 Module[eqn,
 eqn = With[d = 0.8, s = 2, t = 0.02, Evaluate@eq];
 NSolve[Evaluate @ eqn == 0, r]];
Do[rVal[i][c_, q_] = soln[[i, 1, 2]], i, Length[soln]];

Then to get the value of r for the 1st solution with c = .5 and `q = 1.5:

rVal[1][.5, 1.5]

-0.485047

To get all the value of r for all seven solutions at c = .25 and `q = 1.

Through[Array[rVal, 7][.25, 1.]]

-0.524898, 0.519435, 0.792331, 0.986375, 1.19151, 
 0.0176256 - 0.0442494 I, 0.0176256 + 0.0442494 I

Notice that in this last case there are five real solutions.

2nd Edit

Here is an exploration of the seven root objects. Note that two of plots are are empty because two the root objects are never real in the specified domain. Also, you should be able to see where the icicles come from.

Column[
 Table[
 Plot3D[Evaluate[rVal[i][c, q]], c, 0, 1, q, 1, 2, PlotPoints -> 50], 
 i, 7]]

plots

edited 17 mins ago

answered 2 hours ago

m_goldberg

88.1k872199

$begingroup$
Thanks so much! Can you please give me some comments on how to interpret the graphical result? It looks very weird... Why it has layers? What are those icicle-like things? Why change in the color, say from green to purple? Etc... From the graph, what is the approximate value of r for, say, c=0.2 & q=1.2? Isn't it impossible to tell since there are three corresponding values of r? Green, blue, and orange?
$endgroup$
– ppp
2 hours ago

$begingroup$
@ppp. Solve finds seven root functions for your equation, so at any patch of the plot domain, up to seven surfaces could show up. But it seems that only three of the root functions actually evaluate to real values over any significant part of the domain. The icicle-like things are areas where the solver found small patches, evidently with very steep gradients, of a real surface for some of the other possible surfaces.There is also a smallish patch of a red surface which can only be seen when the plot is rotated to different view.
$endgroup$
– m_goldberg
2 hours ago

$begingroup$
@ppp. You can can explore each of the seven root objects returned from Solve individually to find the one that best represents a solution to your problem. Further, you can get a value of r for any pair of c and q from the individual root objects.
$endgroup$
– m_goldberg
1 hour ago

$begingroup$
Do you know how to 'explore each of the root objects returned from Solve individually to find the one that best represents a solution to my problem'? By the way, I have restricted the roots to 0<=r<=1 by adding PlotRange->0,1. It would be desirable to get a unique positive root lying between 0 and 1.
$endgroup$
– ppp
1 hour ago

$begingroup$
One more question: I'm sorry but I'm not quite understanding your comments about the icicle-like things. May I ask your explanation once more? I really appreciate!
$endgroup$
– ppp
1 hour ago

|
show 3 more comments

Your Answer

StackExchange.ifUsing("editor", function ()
return StackExchange.using("mathjaxEditing", function ()
StackExchange.MarkdownEditor.creationCallbacks.add(function (editor, postfix)
StackExchange.mathjaxEditing.prepareWmdForMathJax(editor, postfix, [["$", "$"], ["\$","\$"]]);
);
);
, "mathjax-editing");

StackExchange.ready(function()
var channelOptions =
tags: "".split(" "),
id: "387"
;
initTagRenderer("".split(" "), "".split(" "), channelOptions);

StackExchange.using("externalEditor", function()
// Have to fire editor after snippets, if snippets enabled
if (StackExchange.settings.snippets.snippetsEnabled)
StackExchange.using("snippets", function()
createEditor();
);

else
createEditor();

);

function createEditor()
StackExchange.prepareEditor(
heartbeatType: 'answer',
autoActivateHeartbeat: false,
convertImagesToLinks: false,
noModals: true,
showLowRepImageUploadWarning: true,
reputationToPostImages: null,
bindNavPrevention: true,
postfix: "",
imageUploader:
brandingHtml: "Powered by u003ca class="icon-imgur-white" href="https://imgur.com/"u003eu003c/au003e",
contentPolicyHtml: "User contributions licensed under u003ca href="https://creativecommons.org/licenses/by-sa/3.0/"u003ecc by-sa 3.0 with attribution requiredu003c/au003e u003ca href="https://stackoverflow.com/legal/content-policy"u003e(content policy)u003c/au003e",
allowUrls: true
,
onDemand: true,
discardSelector: ".discard-answer"
,immediatelyShowMarkdownHelp:true
);

);

draft saved

draft discarded

StackExchange.ready(
function ()
StackExchange.openid.initPostLogin('.new-post-login', 'https%3a%2f%2fmathematica.stackexchange.com%2fquestions%2f194463%2fsolving-an-equation-with-constraints%23new-answer', 'question_page');

);

Post as a guest

Name

Required, but never shown

1 Answer
1

active

oldest

votes

1 Answer
1

active

oldest

votes

Making the plot was a little slow because there seem some regions with very steep gradients that Plot3D has trouble with.

eq = (1/(24 (-1 + r)^3 r^4 s) (3 d^6 (-3 + 5 r) (-1 + t) + 6 d^5 (3 - 5 r + c (-3 + r (9 - 4 q + 8 (-1 + q) r))) (-1 + t) + 12 d (-1 + r)^3 r^2 (s + 2 t) - 4 (-1 + r)^3 r^2 s ((-1 + r^2) s (-1 + t) + 3 t) + 12 d^3 (-1 + r) r (2 + c (-2 + r (5 - 2 q + 4 (-1 + q) r)) + s - r (3 + s + r s) + 2 t - 3 r t + (-1 + r + r^2) s t) + 3 d^4 (3 + c^2 (1 + 2 (-1 + q) r) (-3 + r (7 - 2 q + 6 (-1 + q) r)) (-1 + t) - 2 c (-3 + r (9 - 4 q + 8 (-1 + q) r)) (-1 + t) - 3 t + r (3 + 4 r (-5 + 3 r) + 5 t)) + 12 d^2 (-1 + r) r (-(-1 + c) (s (-1 + t) - 2 t) + r^3 (-1 + c (-1 + q) s (-1 + t) - t) + r^2 (2 + (-1 + c (-1 + 2 q)) s (-1 + t) + (2 + 4 c - 4 c q) t) + r (-1 - (1 + c (-2 + q)) s (-1 + t) + (2 - 5 c + 2 c q) t))));

Module[eqn, soln,
 eqn = With[d = 4/5, s = 2, t = 2/100, Evaluate @ eq];
 soln = Solve[Evaluate @ eqn == 0, r];
 Plot3D[Evaluate[r /. soln], c, 0, 1, q, 1, 2, PlotPoints -> 50]]

plot

Edit

This addresses a issue raised by the OP in a comment below.

Here is way to get numerical values of r.

soln =
 Module[eqn,
 eqn = With[d = 0.8, s = 2, t = 0.02, Evaluate@eq];
 NSolve[Evaluate @ eqn == 0, r]];
Do[rVal[i][c_, q_] = soln[[i, 1, 2]], i, Length[soln]];

Then to get the value of r for the 1st solution with c = .5 and `q = 1.5:

rVal[1][.5, 1.5]

-0.485047

To get all the value of r for all seven solutions at c = .25 and `q = 1.

Through[Array[rVal, 7][.25, 1.]]

-0.524898, 0.519435, 0.792331, 0.986375, 1.19151, 
 0.0176256 - 0.0442494 I, 0.0176256 + 0.0442494 I

Notice that in this last case there are five real solutions.

2nd Edit

Column[
 Table[
 Plot3D[Evaluate[rVal[i][c, q]], c, 0, 1, q, 1, 2, PlotPoints -> 50], 
 i, 7]]

plots

edited 17 mins ago

answered 2 hours ago

m_goldberg

88.1k872199

$begingroup$
Thanks so much! Can you please give me some comments on how to interpret the graphical result? It looks very weird... Why it has layers? What are those icicle-like things? Why change in the color, say from green to purple? Etc... From the graph, what is the approximate value of r for, say, c=0.2 & q=1.2? Isn't it impossible to tell since there are three corresponding values of r? Green, blue, and orange?
$endgroup$
– ppp
2 hours ago

$begingroup$
@ppp. Solve finds seven root functions for your equation, so at any patch of the plot domain, up to seven surfaces could show up. But it seems that only three of the root functions actually evaluate to real values over any significant part of the domain. The icicle-like things are areas where the solver found small patches, evidently with very steep gradients, of a real surface for some of the other possible surfaces.There is also a smallish patch of a red surface which can only be seen when the plot is rotated to different view.
$endgroup$
– m_goldberg
2 hours ago

$begingroup$
@ppp. You can can explore each of the seven root objects returned from Solve individually to find the one that best represents a solution to your problem. Further, you can get a value of r for any pair of c and q from the individual root objects.
$endgroup$
– m_goldberg
1 hour ago

$begingroup$
Do you know how to 'explore each of the root objects returned from Solve individually to find the one that best represents a solution to my problem'? By the way, I have restricted the roots to 0<=r<=1 by adding PlotRange->0,1. It would be desirable to get a unique positive root lying between 0 and 1.
$endgroup$
– ppp
1 hour ago

$begingroup$
One more question: I'm sorry but I'm not quite understanding your comments about the icicle-like things. May I ask your explanation once more? I really appreciate!
$endgroup$
– ppp
1 hour ago

|
show 3 more comments

Making the plot was a little slow because there seem some regions with very steep gradients that Plot3D has trouble with.

eq = (1/(24 (-1 + r)^3 r^4 s) (3 d^6 (-3 + 5 r) (-1 + t) + 6 d^5 (3 - 5 r + c (-3 + r (9 - 4 q + 8 (-1 + q) r))) (-1 + t) + 12 d (-1 + r)^3 r^2 (s + 2 t) - 4 (-1 + r)^3 r^2 s ((-1 + r^2) s (-1 + t) + 3 t) + 12 d^3 (-1 + r) r (2 + c (-2 + r (5 - 2 q + 4 (-1 + q) r)) + s - r (3 + s + r s) + 2 t - 3 r t + (-1 + r + r^2) s t) + 3 d^4 (3 + c^2 (1 + 2 (-1 + q) r) (-3 + r (7 - 2 q + 6 (-1 + q) r)) (-1 + t) - 2 c (-3 + r (9 - 4 q + 8 (-1 + q) r)) (-1 + t) - 3 t + r (3 + 4 r (-5 + 3 r) + 5 t)) + 12 d^2 (-1 + r) r (-(-1 + c) (s (-1 + t) - 2 t) + r^3 (-1 + c (-1 + q) s (-1 + t) - t) + r^2 (2 + (-1 + c (-1 + 2 q)) s (-1 + t) + (2 + 4 c - 4 c q) t) + r (-1 - (1 + c (-2 + q)) s (-1 + t) + (2 - 5 c + 2 c q) t))));

Module[eqn, soln,
 eqn = With[d = 4/5, s = 2, t = 2/100, Evaluate @ eq];
 soln = Solve[Evaluate @ eqn == 0, r];
 Plot3D[Evaluate[r /. soln], c, 0, 1, q, 1, 2, PlotPoints -> 50]]

plot

Edit

This addresses a issue raised by the OP in a comment below.

Here is way to get numerical values of r.

soln =
 Module[eqn,
 eqn = With[d = 0.8, s = 2, t = 0.02, Evaluate@eq];
 NSolve[Evaluate @ eqn == 0, r]];
Do[rVal[i][c_, q_] = soln[[i, 1, 2]], i, Length[soln]];

Then to get the value of r for the 1st solution with c = .5 and `q = 1.5:

rVal[1][.5, 1.5]

-0.485047

To get all the value of r for all seven solutions at c = .25 and `q = 1.

Through[Array[rVal, 7][.25, 1.]]

-0.524898, 0.519435, 0.792331, 0.986375, 1.19151, 
 0.0176256 - 0.0442494 I, 0.0176256 + 0.0442494 I

Notice that in this last case there are five real solutions.

2nd Edit

Column[
 Table[
 Plot3D[Evaluate[rVal[i][c, q]], c, 0, 1, q, 1, 2, PlotPoints -> 50], 
 i, 7]]

plots

edited 17 mins ago

answered 2 hours ago

m_goldberg

88.1k872199

$begingroup$
Thanks so much! Can you please give me some comments on how to interpret the graphical result? It looks very weird... Why it has layers? What are those icicle-like things? Why change in the color, say from green to purple? Etc... From the graph, what is the approximate value of r for, say, c=0.2 & q=1.2? Isn't it impossible to tell since there are three corresponding values of r? Green, blue, and orange?
$endgroup$
– ppp
2 hours ago

$begingroup$
@ppp. Solve finds seven root functions for your equation, so at any patch of the plot domain, up to seven surfaces could show up. But it seems that only three of the root functions actually evaluate to real values over any significant part of the domain. The icicle-like things are areas where the solver found small patches, evidently with very steep gradients, of a real surface for some of the other possible surfaces.There is also a smallish patch of a red surface which can only be seen when the plot is rotated to different view.
$endgroup$
– m_goldberg
2 hours ago

$begingroup$
@ppp. You can can explore each of the seven root objects returned from Solve individually to find the one that best represents a solution to your problem. Further, you can get a value of r for any pair of c and q from the individual root objects.
$endgroup$
– m_goldberg
1 hour ago

$begingroup$
Do you know how to 'explore each of the root objects returned from Solve individually to find the one that best represents a solution to my problem'? By the way, I have restricted the roots to 0<=r<=1 by adding PlotRange->0,1. It would be desirable to get a unique positive root lying between 0 and 1.
$endgroup$
– ppp
1 hour ago

$begingroup$
One more question: I'm sorry but I'm not quite understanding your comments about the icicle-like things. May I ask your explanation once more? I really appreciate!
$endgroup$
– ppp
1 hour ago

|
show 3 more comments

Making the plot was a little slow because there seem some regions with very steep gradients that Plot3D has trouble with.

eq = (1/(24 (-1 + r)^3 r^4 s) (3 d^6 (-3 + 5 r) (-1 + t) + 6 d^5 (3 - 5 r + c (-3 + r (9 - 4 q + 8 (-1 + q) r))) (-1 + t) + 12 d (-1 + r)^3 r^2 (s + 2 t) - 4 (-1 + r)^3 r^2 s ((-1 + r^2) s (-1 + t) + 3 t) + 12 d^3 (-1 + r) r (2 + c (-2 + r (5 - 2 q + 4 (-1 + q) r)) + s - r (3 + s + r s) + 2 t - 3 r t + (-1 + r + r^2) s t) + 3 d^4 (3 + c^2 (1 + 2 (-1 + q) r) (-3 + r (7 - 2 q + 6 (-1 + q) r)) (-1 + t) - 2 c (-3 + r (9 - 4 q + 8 (-1 + q) r)) (-1 + t) - 3 t + r (3 + 4 r (-5 + 3 r) + 5 t)) + 12 d^2 (-1 + r) r (-(-1 + c) (s (-1 + t) - 2 t) + r^3 (-1 + c (-1 + q) s (-1 + t) - t) + r^2 (2 + (-1 + c (-1 + 2 q)) s (-1 + t) + (2 + 4 c - 4 c q) t) + r (-1 - (1 + c (-2 + q)) s (-1 + t) + (2 - 5 c + 2 c q) t))));

Module[eqn, soln,
 eqn = With[d = 4/5, s = 2, t = 2/100, Evaluate @ eq];
 soln = Solve[Evaluate @ eqn == 0, r];
 Plot3D[Evaluate[r /. soln], c, 0, 1, q, 1, 2, PlotPoints -> 50]]

plot

Edit

This addresses a issue raised by the OP in a comment below.

Here is way to get numerical values of r.

soln =
 Module[eqn,
 eqn = With[d = 0.8, s = 2, t = 0.02, Evaluate@eq];
 NSolve[Evaluate @ eqn == 0, r]];
Do[rVal[i][c_, q_] = soln[[i, 1, 2]], i, Length[soln]];

Then to get the value of r for the 1st solution with c = .5 and `q = 1.5:

rVal[1][.5, 1.5]

-0.485047

To get all the value of r for all seven solutions at c = .25 and `q = 1.

Through[Array[rVal, 7][.25, 1.]]

-0.524898, 0.519435, 0.792331, 0.986375, 1.19151, 
 0.0176256 - 0.0442494 I, 0.0176256 + 0.0442494 I

Notice that in this last case there are five real solutions.

2nd Edit

Column[
 Table[
 Plot3D[Evaluate[rVal[i][c, q]], c, 0, 1, q, 1, 2, PlotPoints -> 50], 
 i, 7]]

plots

edited 17 mins ago

answered 2 hours ago

m_goldberg

88.1k872199

Making the plot was a little slow because there seem some regions with very steep gradients that Plot3D has trouble with.

eq = (1/(24 (-1 + r)^3 r^4 s) (3 d^6 (-3 + 5 r) (-1 + t) + 6 d^5 (3 - 5 r + c (-3 + r (9 - 4 q + 8 (-1 + q) r))) (-1 + t) + 12 d (-1 + r)^3 r^2 (s + 2 t) - 4 (-1 + r)^3 r^2 s ((-1 + r^2) s (-1 + t) + 3 t) + 12 d^3 (-1 + r) r (2 + c (-2 + r (5 - 2 q + 4 (-1 + q) r)) + s - r (3 + s + r s) + 2 t - 3 r t + (-1 + r + r^2) s t) + 3 d^4 (3 + c^2 (1 + 2 (-1 + q) r) (-3 + r (7 - 2 q + 6 (-1 + q) r)) (-1 + t) - 2 c (-3 + r (9 - 4 q + 8 (-1 + q) r)) (-1 + t) - 3 t + r (3 + 4 r (-5 + 3 r) + 5 t)) + 12 d^2 (-1 + r) r (-(-1 + c) (s (-1 + t) - 2 t) + r^3 (-1 + c (-1 + q) s (-1 + t) - t) + r^2 (2 + (-1 + c (-1 + 2 q)) s (-1 + t) + (2 + 4 c - 4 c q) t) + r (-1 - (1 + c (-2 + q)) s (-1 + t) + (2 - 5 c + 2 c q) t))));

Module[eqn, soln,
 eqn = With[d = 4/5, s = 2, t = 2/100, Evaluate @ eq];
 soln = Solve[Evaluate @ eqn == 0, r];
 Plot3D[Evaluate[r /. soln], c, 0, 1, q, 1, 2, PlotPoints -> 50]]

plot

Edit

This addresses a issue raised by the OP in a comment below.

Here is way to get numerical values of r.

soln =
 Module[eqn,
 eqn = With[d = 0.8, s = 2, t = 0.02, Evaluate@eq];
 NSolve[Evaluate @ eqn == 0, r]];
Do[rVal[i][c_, q_] = soln[[i, 1, 2]], i, Length[soln]];

Then to get the value of r for the 1st solution with c = .5 and `q = 1.5:

rVal[1][.5, 1.5]

-0.485047

To get all the value of r for all seven solutions at c = .25 and `q = 1.

Through[Array[rVal, 7][.25, 1.]]

-0.524898, 0.519435, 0.792331, 0.986375, 1.19151, 
 0.0176256 - 0.0442494 I, 0.0176256 + 0.0442494 I

Notice that in this last case there are five real solutions.

2nd Edit

Column[
 Table[
 Plot3D[Evaluate[rVal[i][c, q]], c, 0, 1, q, 1, 2, PlotPoints -> 50], 
 i, 7]]

plots

edited 17 mins ago

answered 2 hours ago

m_goldberg

88.1k872199

edited 17 mins ago

answered 2 hours ago

m_goldberg

88.1k872199

answered 2 hours ago

m_goldberg

88.1k872199

answered 2 hours ago

m_goldberg

88.1k872199

$begingroup$
Thanks so much! Can you please give me some comments on how to interpret the graphical result? It looks very weird... Why it has layers? What are those icicle-like things? Why change in the color, say from green to purple? Etc... From the graph, what is the approximate value of r for, say, c=0.2 & q=1.2? Isn't it impossible to tell since there are three corresponding values of r? Green, blue, and orange?
$endgroup$
– ppp
2 hours ago

$begingroup$
@ppp. Solve finds seven root functions for your equation, so at any patch of the plot domain, up to seven surfaces could show up. But it seems that only three of the root functions actually evaluate to real values over any significant part of the domain. The icicle-like things are areas where the solver found small patches, evidently with very steep gradients, of a real surface for some of the other possible surfaces.There is also a smallish patch of a red surface which can only be seen when the plot is rotated to different view.
$endgroup$
– m_goldberg
2 hours ago

$begingroup$
@ppp. You can can explore each of the seven root objects returned from Solve individually to find the one that best represents a solution to your problem. Further, you can get a value of r for any pair of c and q from the individual root objects.
$endgroup$
– m_goldberg
1 hour ago

$begingroup$
Do you know how to 'explore each of the root objects returned from Solve individually to find the one that best represents a solution to my problem'? By the way, I have restricted the roots to 0<=r<=1 by adding PlotRange->0,1. It would be desirable to get a unique positive root lying between 0 and 1.
$endgroup$
– ppp
1 hour ago

$begingroup$
One more question: I'm sorry but I'm not quite understanding your comments about the icicle-like things. May I ask your explanation once more? I really appreciate!
$endgroup$
– ppp
1 hour ago

|
show 3 more comments

$begingroup$
Thanks so much! Can you please give me some comments on how to interpret the graphical result? It looks very weird... Why it has layers? What are those icicle-like things? Why change in the color, say from green to purple? Etc... From the graph, what is the approximate value of r for, say, c=0.2 & q=1.2? Isn't it impossible to tell since there are three corresponding values of r? Green, blue, and orange?
$endgroup$
– ppp
2 hours ago

$begingroup$
@ppp. Solve finds seven root functions for your equation, so at any patch of the plot domain, up to seven surfaces could show up. But it seems that only three of the root functions actually evaluate to real values over any significant part of the domain. The icicle-like things are areas where the solver found small patches, evidently with very steep gradients, of a real surface for some of the other possible surfaces.There is also a smallish patch of a red surface which can only be seen when the plot is rotated to different view.
$endgroup$
– m_goldberg
2 hours ago

$begingroup$
@ppp. You can can explore each of the seven root objects returned from Solve individually to find the one that best represents a solution to your problem. Further, you can get a value of r for any pair of c and q from the individual root objects.
$endgroup$
– m_goldberg
1 hour ago

$begingroup$
Do you know how to 'explore each of the root objects returned from Solve individually to find the one that best represents a solution to my problem'? By the way, I have restricted the roots to 0<=r<=1 by adding PlotRange->0,1. It would be desirable to get a unique positive root lying between 0 and 1.
$endgroup$
– ppp
1 hour ago

$begingroup$
One more question: I'm sorry but I'm not quite understanding your comments about the icicle-like things. May I ask your explanation once more? I really appreciate!
$endgroup$
– ppp
1 hour ago

Thanks so much! Can you please give me some comments on how to interpret the graphical result? It looks very weird... Why it has layers? What are those icicle-like things? Why change in the color, say from green to purple? Etc... From the graph, what is the approximate value of r for, say, c=0.2 & q=1.2? Isn't it impossible to tell since there are three corresponding values of r? Green, blue, and orange?

– ppp
2 hours ago

@ppp. Solve finds seven root functions for your equation, so at any patch of the plot domain, up to seven surfaces could show up. But it seems that only three of the root functions actually evaluate to real values over any significant part of the domain. The icicle-like things are areas where the solver found small patches, evidently with very steep gradients, of a real surface for some of the other possible surfaces.There is also a smallish patch of a red surface which can only be seen when the plot is rotated to different view.

– m_goldberg
2 hours ago

@ppp. You can can explore each of the seven root objects returned from Solve individually to find the one that best represents a solution to your problem. Further, you can get a value of r for any pair of c and q from the individual root objects.

– m_goldberg
1 hour ago

Do you know how to 'explore each of the root objects returned from Solve individually to find the one that best represents a solution to my problem'? By the way, I have restricted the roots to 0<=r<=1 by adding PlotRange->0,1. It would be desirable to get a unique positive root lying between 0 and 1.

– ppp
1 hour ago

One more question: I'm sorry but I'm not quite understanding your comments about the icicle-like things. May I ask your explanation once more? I really appreciate!

– ppp
1 hour ago

|
show 3 more comments

draft saved

draft discarded

Thanks for contributing an answer to Mathematica Stack Exchange!

Please be sure to answer the question. Provide details and share your research!

But avoid …

Asking for help, clarification, or responding to other answers.

Making statements based on opinion; back them up with references or personal experience.

Use MathJax to format equations. MathJax reference.

To learn more, see our tips on writing great answers.

draft saved

draft discarded

Post as a guest

Name

Required, but never shown

Name

Required, but never shown

Name

Required, but never shown

This page is only for reference, If you need detailed information, please check here

搜尋此網誌

Yhyjyk

1 Answer
1

Edit

2nd Edit

Your Answer

Post as a guest

1 Answer
1

1 Answer
1

Edit

2nd Edit

Edit

2nd Edit

Edit

2nd Edit

Edit

2nd Edit

Post as a guest

Popular posts from this blog

1 Answer 1

Edit

2nd Edit

Your Answer

Sign up or log in

Post as a guest

Post as a guest

1 Answer 1

1 Answer 1

Edit

2nd Edit

Edit

2nd Edit

Edit

2nd Edit

Edit

2nd Edit

Sign up or log in

Post as a guest

Post as a guest

Sign up or log in

Post as a guest

Sign up or log in

Post as a guest

Sign up or log in

Post as a guest

Popular posts from this blog

1 Answer
1

1 Answer
1

1 Answer
1